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DRIVER’S MANUAL FOR THE
SAFE SECUREMENTOF
METAL COILSAND
OTHER CARGO
INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . i
Driver License Class Descriptions . . . . . . . . . . . . . . . . . ii
SECTION 1 — Fundamentals of Cargo Securement . . . . . . 1.1 - 1.6
General Requirements . . . . . . . . . . . . . . . . . . . . . . . . . . 1.1
Consequences for Drivers Who Do
Not Follow the Rules . . . . . . . . . . . . . . . . . . . . . . . . 1.1
Specific Securement Requirements for Metal Coils . . . 1.2
Performance Criteria for Securement Systems . . . . . . . 1.3 - 1.5
PART I - Cargo Securement Performance Criteria . . . 1.3 - 1.4
Fully Contained Cargo . . . . . . . . . . . . . . . . 1.5
PART II - Components of a Securement System . . . . 1.5
TEST YOUR KNOWLEDGE. . . . . . . . . . . . . . . . . . . 1.6
SECTION 2 — General Provisions and Requirements . . . . . 2.1 - 2.19
What is a Securement System . . . . . . . . . . . . . . . . . . . . 2.1
Failure Modes for Securement Systems. . . . . . . . . . . . . 2.1
Objectives for Securement Equipment and Devices . . . 2.1
Securement System Elements . . . . . . . . . . . . . . . . . . . . 2.2
Category 1
Vehicle Structure and Anchor Points . . . . . . . . . . . 2.2
Cargo Securement Responsibility . . . . . . . . . . . . . . 2.2
Cab Shields . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.3
Category 2
Securement Method . . . . . . . . . . . . . . . . . . . . . . . . . 2.3
Category 3
Securement Devices, Assemblies and Components -
Packaging . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.4
Securement Devices, Assemblies and Components -
Tiedowns: Direct and Indirect . . . . . . . . . . . . . . 2.4 - 2.5
Tiedown Condition and Maintenance . . . . . . . . . . . 2.5
Responsibility for Tightening Tiedowns . . . . . . . . . 2.5
Location of Tiedowns . . . . . . . . . . . . . . . . . . . . . . . 2.5
Use of Edge Protection . . . . . . . . . . . . . . . . . . . . . . 2.6
Category 4
Dunnage Materials . . . . . . . . . . . . . . . . . . . . . . . . . . 2.6
Securement Options . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.7
Working Load Limit (WLL) . . . . . . . . . . . . . . . . . . . . . 2.7
WLL Table . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.8
TABLE OF CONTENTS
SECTION 2 (CON’T)
Strength Rating for Blocking Systems. . . . . . . . . . . . . . 2.9
Securement System Strength Rating for
Marked Components . . . . . . . . . . . . . . . . . . . . . . . . 2.10
Cargo Placement and Restraint . . . . . . . . . . . . . . . . . . . . . 2.11
Cargo Roll Prevention. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.12
Aggregate Working Load Limit for Tiedowns . . . . . . . . 2.13
Purpose of Direct Tiedowns . . . . . . . . . . . . . . . . . . . . . . 2.14
Angles Required When Using Direct Tiedowns . . . . . . 2.14
Calculating Working Load Limits for
Direct Tiedowns . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.15
Purpose of Indirect Tiedowns. . . . . . . . . . . . . . . . . . . . . 2.15
Angles Required for Using Indirect Tiedowns. . . . . . . . 2.16
Calculating Working Load Limits for
Indirect Tiedowns. . . . . . . . . . . . . . . . . . . . . . . . . . . 2.17
Minimum Number of Indirect Tiedowns Required . . . . 2.17 - 2.18
Inspection of Securement Systems. . . . . . . . . . . . . . . . . 2.18
TEST YOUR KNOWLEDGE . . . . . . . . . . . . . . . . . . . . 2.19
SECTION 3 — Metal Coils . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1 - 3.11
Preventing Securement Failure . . . . . . . . . . . . . . . . . . . 3.1
Application . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1
Coil Orientation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2
Securement Requirements for a Single Metal Coil
With Eyes Vertical . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3
Securement Requirements for a Row of Metal Coils
With Eyes Vertical . . . . . . . . . . . . . . . . . . . . . . . . . . 3.4
Securement Requirements for Metal Coils
With Eyes Crosswise . . . . . . . . . . . . . . . . . . . . . . . . 3.5 - 3.6
Securement Requirements for Individual Metal Coils
With Eyes Lengthwise. . . . . . . . . . . . . . . . . . . . . . . . . . 3.7 - 3.8
Securement Requirements for a Row of Metal Coils
With Eyes Lengthwise . . . . . . . . . . . . . . . . . . . . . . . . . 3.9
Securement Requirements for Metal Coils in
Sided Vehicles or Intermodal Containers without
Anchor Points. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.10
TEST YOUR KNOWLEDGE . . . . . . . . . . . . . . . . . . . . 3.11
DEFINITIONS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1 - 4.2
Cover photo courtesy of Riverside Services
Cargo being transported on the highway must remain secured on or within
the transporting vehicle. The Federal Motor Carrier Safety Administration
(FMCSA) has established regulations in Title 49 CFR Part 393.100-136 that
specify proper loading and securement requirements for cargo transported on
public roads by commercial motor vehicles (CMVs). The regulations may be
accessed at www.FMCSA.dot.gov (search: 49 CFR 393).
Although these regulations, by Federal definition, pertain to interstate
transportation by commercial transporters, they have been adopted by all
states, including New York, for commercial transportation (New York
State Transportation Law Section 140 together with Commissioner’s
Regulation 17 NYCRR 820.5 and New York State Vehicle & Traffic Law
Sections 377-378 together with Commissioner’s Regulation 15 NYCRR 48.1).
The intent of the regulations is to prevent/reduce the number of crashes
caused by cargo shifting on, within, or falling from ALL vehicles
operating in New York State.
The regulations include general cargo securement rules for all types of cargo
(with certain exceptions); those rules are covered in this manual. There are
also some commodity-specific rules for certain products, including metal
coils. The metal coil specific rules are also explained in this manual.
You need a New York State commercial driver license (CDL) with a
metal coil endorsement (M) if you are driving a CMV as defined in New
York State Vehicle and Traffic Law §501-a(4) and transporting 5,000 or
more pounds of metal coil. Section 501(2)(b)(ix) of the New York State
Vehicle and Traffic Law together with Commissioner’s Regulations 15
NYCRR 3.2(b)(1)(i), (a) and (b) require the metal coil endorsement when
transporting metal coils within the state that, individually or bundled
together, weigh 5,000 pounds or more. CMV operators licensed by
another state are not required to have this endorsement when transporting
metal coils through New York State.
You must hold a Class A, B or C license and pass a written metal coil
knowledge test to qualify for the metal coil endorsement (it will be
identified as the code “M” on the endorsement section of your license).
The metal coil knowledge test is based on the material presented in this
manual. Cargo securement terms are italicized throughout the manual
and are defined on pages 4.1 and 4.2. At the test site, you will be given a
copy of the Working Load Limit Table (see page 2.7) to use in answering
some of the test questions. i
INTRODUCTION
ii
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General Requirements of Title 49 Code of Federal Regulations
Part 393 §100-136 (Subpart I); Regulations for Protection
Against Shifting and Falling Cargo
Cargo being transported on the highway must remain secured on or
within the transporting vehicle under all conditions that could reasonably
be expected to occur in normal driving. This includes when a driver is
responding in an emergency situation, except when there is a crash.
Federal cargo securement rules apply to trucks, truck tractors, semi-
trailers, full trailers and tractor-pole trailers with a gross vehicle weight
rating of more than 10,000 lbs. When transporting cargo on public roads,
commercial vehicles must be loaded and equipped and the cargo secured
so that it does not:
l Leak
l Spill
l Blow off the vehicle
l Fall from the vehicle
l Fall through the vehicle
l Otherwise become dislodged from the vehicle
l Swing or shift, making the vehicle unstable or adversely affecting
maneuverability
Consequences for Drivers Who Do Not Follow the Cargo
Securement Rules
An improperly secured load can result in:
l A crash
l Loss of life; personal injury
l Loss of load
l Damage to the cargo
l Damage to the vehicle
l Issuance of citations/fines to the driver/carrier
l The vehicle being placed Out of Service
1.1
SECTION 1 FUNDAMENTALS OF CARGO SECUREMENT
Specific Securement Requirements for Metal Coils
In addition to the general requirements for cargo securement, there are
additional federal requirements for certain commodities (see 49 CFR
§393.116 - 393.136). If additional requirements exist for a commodity,
those commodity-specific rules take precedence over the general cargo
securement requirements.
Metal Coils are one of those commodities. A metal coil is defined as a
product comprised of mixtures, compounds and/or alloys commonly
known as metal, metal foil, metal leaf, forged metal, stamped metal,
metal wire or metal chain that are generally good conductors of electricity
and heat and can be melted or fused, hammered into thin sheets, or drawn
into wire, and that are bulk packaged or packaged from a continuous pull
or multiple pulls as a roll, coil, spool, wind or wrap.
The rules for securing metal coils are listed in 49 CFR §393.120. The
rules apply to the transportation of one or more metal coils which,
individually or grouped together, weigh 5,000 lbs. or more. Shipments of
metal coils that weigh less than 5,000 lbs. may be secured in accordance
with the general cargo securement rules.
1.2
Performance Criteria for Securement Systems
PART I - Cargo Securement Performance Criteria
The FMCSA requirements establish the minimum amount of force that a
cargo securement system must be able to withstand. These minimum
force requirements, called the “performance criteria”, were determined
after extensive testing. Each securement system MUST be able to
withstand a minimum amount of force in each direction, as shown below.
l The forward force =80% of the cargo weight when braking while
driving straight ahead (decelerating).
l The rearward force =50% of the cargo weight when accelerating or
braking in reverse.
l The side-to-side or lateral force =50% of the cargo weight when
traveling on a curve or ramp, changing lanes or turning.
1.3
50% of cargo weight
50% of cargo weight
80% of cargo weight
50% of cargo weight
The performance criteria may also be expressed in terms of acceleration,
which is shown above (“g” is the term used for gravity, and represents
acceleration or deceleration).
l 0.8 g deceleration in the forward direction
l 0.5 g acceleration in the rearward direction
l 0.5 g acceleration in a side-to-side or lateral direction
EXAMPLE: If a steel coil weighs 10,000 lbs., the load securement must
provide 8,000 lbs. of securement to prevent movement in the forward
direction, which is expressed as 80% of the cargo weight (or 0.8 g).
1.4
PART I (con’t)
"Fully Contained" Cargo
"Fully contained" means that the cargo is placed against a vehicle structure
of adequate strength or other cargo so that it cannot shift or tip. Cargo that
fills a sided vehicle of adequate strength is considered fully contained.
PART II - Performance Criteria for Components of a
Securement System
Each component of the cargo securement system should not exceed its
Working Load Limit (WLL), when at maximum force. The Working Load
Limit is the maximum load that may be applied to a component of a cargo
securement system during normal service; it is usually assigned by the
manufacturer of the component.
Each force in the performance criteria is to be applied separately to the
securement system to determine if it is compliant.
Components of a Securement System
1.5
1. What types of commercial vehicles are required to comply with the
cargo securement regulations?
2. What is the minimum amount of force that a cargo securement system
should be expected to withstand when traveling on a curve, ramp or
when changing lanes?
3. If an aluminum coil weighs 12,000 lbs., the load securement must
provide 6,000 lbs. of securement to prevent movement in the
rearward direction. How is this performance criteria expressed in
terms of gravity (“g”)?
4. What is the definition of Working Load Limit (WLL)?
1.6
TEST YOUR KNOWLEDGE OF SECTION 1
SECTION 2 GENERAL PROVISIONS AND REQUIREMENTS
What is a Securement System?
A securement system is a securement method that uses one or a
combination of the following elements: vehicle structure, securing
devices, and/or blocking and bracing equipment. The securement
system chosen must be appropriate for the cargo’s size, shape, strength
and characteristics.
Failure Modes for Securement Systems
When cargo is subjected to the forces in the performance criteria
(Section 1), and when the securement system is not adequate, the system
will fail in one of the following three failure modes:
l rolling
l sliding
l tipping
Objectives for Securement Equipment and Devices
It is the responsibility of drivers, shippers, motor carriers and enforcement
personnel to ensure that all securement equipment, devices and the vehicle
structure are in good working order and are used within their capability
and in accordance with the manufacturer’s instructions.
2.1
50% of cargo weight
50% of cargo weight
80% of cargo weight
50% of cargo weight
Securement System ElementsSecurement system elements are described in the following categories:
l Category 1- Vehicle Structure and Anchor Points, Cargo Securement
Responsibility and Cab Shields
l Category 2 - Securement Methods
l Category 3 - Devices, Assemblies and Components
l Category 4 - Dunnage Materials
CATEGORY 1
Vehicle Structure and Anchor Points
The vehicle must be strong enough to resist the forces in the
performance criteria (Section 1). The vehicle must be appropriate for the
cargo it is to transport, or it must be adapted to be suitable by using
fittings, fixtures, dunnage, cribbing or other means.
(Photo courtesy of: Doepker Industries Ltd)
Cargo Securement Responsibility
According to federal and state regulations, the motor carrier and driver
are responsible for ensuring that the vehicles, anchor points and other
securement components are in good working order, with no obvious
signs of damage. The driver is also required to conduct a pre-trip
inspection by other operating regulations.
Roadside inspections are conducted in accordance with federal, state and
provincial laws. If securement equipment fails inspection, it is likely
that the vehicle may be placed out of service, and the motor carrier
and/or the driver may be fined.
2.2
2.3
Cab Shields
A cab shield is a safety device mounted to the tractor.
CATEGORY 2
Securement Method
Because cargo varies in size, shape, weight and other properties, the
shipper and the carrier should devise a securement method that is suited
to the characteristics of their cargo, and that meets the performance
criteria (Section 1).
(Illustration courtesy of: Gouvernement du Québec Ministère des Transports)
2.4
Direct Tiedowns
CATEGORY 3
Securement Devices, Assemblies and Components - Packaging
If a package collapses in transit after the tiedowns are tensioned, thetiedowns become loose and parts of the load may fall from the vehicle.Because the shipper usually packages cargo, the shipper needs to makesure that the packages are strong enough to withstand the forces duringtransport (see the performance criteria in Section 1). After the drivercompletes an inspection, it is the responsibility of the driver to informthe carrier if the packaging is not adequate.
Securement Devices, Assemblies and Components - Tiedowns
A tiedown is made up of an assembly (combination) of securing devices that
restrains cargo on a trailer or vehicle. A tiedown can be attached to anchor
points on the vehicle, or the vehicle might have provisions where a tiedown
can pass through points on the vehicle and be attached to itself.
There are two types of tiedowns that are used to restrain cargo:
direct tiedowns and indirect tiedowns.
l Direct tiedowns are attached to the vehicle and attached to the
cargo. Direct tiedowns also include tiedowns that are attached to the
vehicle, pass through or around an article of cargo, then attach to the
vehicle again. Direct tiedowns provide direct resistance to oppose the
forces that are acting on the cargo. This direct resistance keeps the
cargo in place, and prevents movement.
l Indirect tiedowns are attached to the vehicle, passed over the
cargo, and then are attached to the vehicle again. Indirect tiedowns
create a downward force that increases the effect of friction between
the cargo and the deck. This friction restrains the cargo.
Tiedown Condition and Maintenance
All components of a tiedown must be in proper working condition.
Tiedown assemblies (including chains, wire rope, steel strapping,
synthetic webbing and cordage) and other attachment or fastening
devices used to secure articles of cargo to, or in, commercial motor
vehicles must not contain knots. If any component of a tiedown is
repaired, it must be repaired in accordance with the applicable standards
in 49 CFR §393.104 (e), or the manufacturer’s instructions.
Responsibility for Tightening Tiedowns
Tiedowns (except for steel strapping) must be designed, constructed and
maintained so they can be tightened by the driver. Each tiedown must be
attached and secured in a manner that prevents it from loosening,
unfastening, opening or releasing while the vehicle is in transit.
Location of Tiedowns
All tiedowns and other components of a cargo securement system used
to secure loads on a trailer equipped with rub rails should be located
inboard of the rub rails whenever practicable (this does not apply when
the load extends beyond the rub rails).
2.5
Indirect Tiedowns
Use of Edge Protection
Edge protection must be used whenever a tiedown would be subject to
abrasion or cutting at the point where it touches an article of cargo. The
edge protection must resist abrasion, cutting and crushing. An edge
protection device should fit properly on the edge of the article and must
be secured so that there is no gap between the device and the cargo,
thereby preventing it from being crushed.
.
CATEGORY 4
Dunnage Materials
Timber used between tiedowns and cargo must be strong enough not to
split or be crushed.
Any timber used should be properly seasoned, and free of rot or decay. The
grain should run lengthwise along the timber when it is used for structural
purposes like blocking and bracing. Timber should be free of knots,
knotholes and splits that may affect its strength or interfere with nailing.
2.6
Edge Protection
Securement Options
All types of cargo must satisfy one of the following three conditions
when being secured:
l fully contained by structures of adequate strength, or
Dump Bodies Tankers
l immobilized by structures of adequate strength to prevent shifting
or tipping, or
l immobilized on or within a vehicle by appropriate means to
prevent shifting or tipping.
Note: If additional securement is required for a specific commodity (such
as metal coils), the specific requirements for securing that
commodity take precedence.
Working Load Limit
The Working Load Limit is the maximum load that may be applied to a
component of a cargo securement system during normal service. This value
is assigned by the component manufacturer or the default rating in the
Working Load Limit Table (see page 2.8).
Note: Welded steel chain that is not marked or labeled with a grade or
working load limit is considered to have a working load limit
equal to that for grade 30 proof coil chain.
2.7
2.8
WORKING LOAD LIMIT (WLL) TABLE
Wire Rope
(6 x 37 Fiber Core)
Diameter
(inches)
WLL
(pounds)
5/16 2,100
3/8 3,000
7/16 4,100
5/8 8,300
1/2 5,300
7/8 16,100
3/4 10,900
1/4 1,400
1 20,900
ChainSize
(inches)
WLL
(pounds)
Chain Mark Examples:
Example 1 3 4 7 8 10
1/4 1,300 2,600 3,150 3,500 4,300
5/16 1,900 3,900 4,700 4,500 5,700
3/8 2,650 5,400 6,600 7,100 8,800
7/16 3,700 7,200 8,750
1/2 4,500 9,200 11,300 12,000 15,000
5/8 6,900 13,000 15,800 18,100 22,600
Example 2 30 43 70 80 100
Example 3 300 430 700 800 1000
Polypropylene
Fiber Rope
(3-Strand and 8-Strand
Constructions)
Diameter
(inches)WLL
(pounds)
Polyester
Fiber Rope
(3-Strand and 8-Strand
Constructions)
Diameter
(inches)WLL
(pounds)
Nylon Rope
Diameter
(inches)
WLL
(pounds)
Double Braided
Nylon Rope
Diameter
(inches)WLL
(pounds)
3/8 400
7/16 525
1/2 625
5/8 925
3/4 1,275
1 2,100
3/8 555
7/16 750
1/2 960
5/8 1,500
3/4 1,880
1 3,300
3/8 278
7/16 410
1/2 525
5/8 935
3/4 1,420
1 2,520
3/8 336
7/16 502
1/2 655
5/8 1,130
3/4 1,840
1 3,250
Grade 30
Proof coil
Grade 43
HighGrade 70
Transport
Grade 80
AlloyGrade 100
Alloy
Manila Rope Steel Strapping Synthetic Webbing
Diameter
(inches)
WLL
(pounds)Width x thickness
(inches)
WLL
(pounds)Diameter
(inches)
WLL
(pounds)
3/8 205
7/16 265
1/2 315
5/8 465
3/4 640
1 1,050
1-1/4 x .029 1,190
1-1/4 x .031 1,190
1-1/4 x .035 1,190
1-1/4 x .044 1,690
1-1/4 x .050 1,690
1-1/4 x .057 1,925
2 x .044 2,650
2 x .050 2,650
1-3/4 1,750
2 2,000
3 3,000
4 4,000
MV-79C (3/17)
Strength Rating for Blocking Systems
The working load limit of all components used to block cargo from
forward movement must be 50% (or more) of the weight of the article
being blocked.
The most important securement task is to prevent an article from moving
forward, and the best way to prevent forward movement is to immobilize
the cargo.
This can be done by placing it against a headboard, bulkhead, stakes or
other vehicle structure, or against other cargo that is immobilized in that
manner. Blocking and bracing can be placed between the article and
vehicle structure, other cargo, or a void-filler. A “void-filler” is material
used to fill a space between articles of cargo and the structure of the
vehicle, that has sufficient strength to prevent movement of the articles
of cargo (for example, 4 ft. x 4 ft. timbers placed between two adjacent
articles of cargo to fill the void).
A direct tiedown can also be used to secure cargo against forward
movement (see page 2.13)
2.9
Securement System Strength Rating for Marked Components
The working load limit of a tiedown is the working load limit of its
weakest part, including anchor points (that is, a tiedown is only as strong
as its weakest link). In the case of synthetic webbing, the working load
limit is the working load limit of the tiedown assembly or the anchor
point, whichever is the least.
Some manufacturers mark their manufactured tiedown assemblies, or
components, with a numeric Working Load Limit value. In the absence
of other information, this value should be used as the working load limit
of the component or assembly.
Other manufacturers mark components using a code or symbol that is
defined in a recognized standard. For example, a piece of grade 7 chain
may be marked with a 7 or 70, in accordance with the standard of the
National Association of Chain Manufacturers. The standard then gives
the Working Load Limit for that piece of chain, depending on its size.
Securement System Strength Rating for Unmarked Components
Securement components and assemblies which are not marked are
considered to have working load limits as specified in the Working Load
Limit Table (see page 2.7).
Note: If markings cannot be read, the tiedown will be
considered unmarked.
Carriers should try to purchase and use components that are rated and
marked by their manufacturer. That way, the carrier, driver, shipper and
inspector can all verify that the proper equipment is being used for the job.
Note: Friction mats provide a resistance to horizontal movement equal
to 50% of the cargo weight that is resting on the mat.
2.10
Cargo Placement and Restraint
Articles of cargo that are placed beside each other and secured by side-
to-side, indirect tiedowns must be either:
l placed in direct contact with each other, or
l prevented from shifting towards each other
Some tiedowns lose their initial tension very quickly in normal driving if
there are gaps between articles. Articles must be placed in contact with
each other to ensure that there are no gaps, or must be secured by some
means to prevent them from moving towards each other in transit. This
requirement applies to all layers and stacks of articles that are loaded
across a vehicle.
Where two or more long articles (like metal ingots or bundles of
reinforcing bars) are loaded lengthwise on a vehicle, if the space
between articles cannot be filled with other cargo or blocking, transverse
tiedowns can be wrapped around each article to immobilize it against
side-to-side movement.
2.11
Acceptable Cargo Placement
Cargo Roll Prevention
(i) A means ( e.g., timbers, chocks or wedges, a cradle, etc.) to prevent the
coil from rolling. The means of preventing rolling must support the coil off
the deck, and must not be capable of becoming unintentionally unfastened
or loose while the vehicle is in transit. If timbers, chocks or wedges are used,
they must be held in place by coil bunks or similar devices to prevent them
from coming loose. The use of nailed blocking or cleats as the sole means to
secure timbers, chocks or wedges, or a nailed wood cradle, is prohibited;
(ii) At least one tiedown through its eye, restricting against forward
motion, and whenever practicable, making an angle no more than 45
degrees with the floor of the vehicle or intermodal container when
viewed from the side of the vehicle or container; and
(iii) At least one tiedown through its eye, restricting against rearward
motion, and whenever practicable, making an angle no more than 45
degrees with the floor of the vehicle or intermodal container when
viewed from the side of the vehicle or container
A cradle is a very effective way to prevent rolling. Cradles that have
angles of 45 degrees provide the most restraining force. As the cradle
angle decreases from 45 degrees, so does the restraining force.
Where multiple similar articles are placed against each other, the
tendency to rock can be controlled if tiedowns through the two end
articles pull the articles together, as required for multiple coils.
Attaching tiedowns diagonally through the eye of a coil to form an X-
pattern when viewed from above the vehicle is prohibited.2.12
Aggregate Working Load Limit for Tiedowns
The sum of the working load limits from all tiedowns must be at least
50% of the weight of the cargo.
The aggregate working load limit is the sum of:
(1) One-half the working load limit of each tiedown that goes from an
anchor point on the vehicle to an anchor point on an article of cargo;
(2) One-half the working load limit of each tiedown that is attached to an
anchor point on the vehicle, passes through, over, or around the article of
cargo, and is then attached to an anchor point on the same side of the
vehicle.
(3) The working load limit for each tiedown that goes from an anchor
point on the vehicle, through, over, or around the article of cargo, and
then attaches to another anchor point on the other side of the vehicle.
This is the minimum requirement. More tiedown capacity should be
used if it is needed to secure an article against any movement.
2.13
50% of cargo weight
50% of cargo weight
80% of cargo weight
50% of cargo weight
Purpose of Direct Tiedowns
A direct tiedown resists the performance criteria forces that are applied
to the cargo.
Angles Required When Using Direct Tiedowns
A direct tiedown is considered effective against forward and rearward
forces if it makes an angle less than 45 degrees when viewed from the
side of the vehicle.
A direct tiedown is considered effective against side-to-side forces if it
makes an angle less than 45 degrees with the horizontal when viewed
from the front or rear of the vehicle.
2.14
Force from Performance Criteria
“Direct” tiedowns to resist the
Performance Criteria force
Calculating Working Load Limits for Direct Tiedowns
When calculating the aggregate working load limit of all direct tiedowns,
count 100% of the tiedown working load limit for each tiedown attached
to both sides of the vehicle, as shown in Figure #1, and 50% of the
working load limit for each tiedown attached to only one side of the
vehicle, as shown in Figure #2. If each tiedown has a working load limit of
4,000 lbs. in the figures below, the aggregate working load limit for the
securement system shown in Figure #1 is 8,000 lbs. Each tiedown is
connected to the vehicle TWICE. In figure #2 each tiedown is connected
to the vehicle once, and the aggregate working load limit for all tiedowns
is 4,000 lbs.
Figure #1 Figure #2
Purpose of Indirect Tiedowns
The purpose of the indirect tiedown is to increase the pressure of the
article on the deck (that is, to increase the frictional force between the
article and the deck).
An indirect tiedown has failed if the article shifts. If friction is low between
the deck and the cargo (such as a plastic skid, plastic-coated article, or an oil-
soaked/wet deck), direct tiedowns can be more effective. Under these
conditions, consider using friction mats or other friction enhancing devices.
2.15
Force from Performance Criteria “Indirect” tiedowns to resist the
Performance Criteria force
Angles Required for Using Indirect Tiedowns
An indirect tiedown that is used to prevent front-to-back cargo
movement must make an angle of at least 30 degrees with the deck when
viewed from the side of the vehicle.
An indirect tiedown that is used to prevent side-to-side movement must
make an angle of at least 30 degrees when viewed from the front or back
of the vehicle.
An indirect tiedown should be tensioned to as high an initial tension as
possible, at least 50% of its working load limit. The tension should be
maintained throughout the trip.
2.16
Calculating Working Load Limits for Indirect Tiedowns
Each tiedown that passes over an article is considered to be 1 tiedown.
The aggregate working load limit of all indirect tiedowns is the sum of the
working load limits of each indirect tiedown. In this picture, if each tiedown
has a working load limit of 4,000 lbs., the aggregate working load limit for
this securement system is 8,000 lbs.
2 tiedowns x 4,000 lbs. = 8,000 lbs.
Minimum Number of Indirect Tiedowns Required
When cargo is not prevented from forward movement (by using a
headboard, bulkhead, other cargo or direct tiedown), it must be secured using
the following requirements [METAL COILS HAVE SPECIFIC
REQUIREMENTS]:
2.17
Minimum Number of
Indirect Tiedowns
Article
Description
5 ft. or shorter;
1,100 lbs. or lighter
5 ft. or shorter;
over 1,100 lbs.
1
2
Longer than 5 ft., up to and
including 10 ft.
Longer than 10 ft.
2
2 + 1 tiedown for every
additional 10 ft., or part thereof
When cargo is prevented from forward movement (by using a headboard,
bulkhead, other cargo or direct tiedown) it must be secured using the following
requirements [METAL COILS HAVE SPECIFIC REQUIREMENTS]:
Inspection of Securement SystemsThe driver is responsible for the following cargo securement inspection
activities:
If adjustments need to be made at any inspection, the driver must make
them, or must add devices (as necessary) to ensure that the load is
properly secured. This means that the vehicle should carry, or be
equipped with, additional tiedowns for this purpose.
The driver may be unable to make the inspection if the vehicle is sealed, or
if the securement cannot be inspected. There may also be some loads
where the driver cannot adjust the securing devices. However, the
responsibility for cargo securement still exists, as explained in Section 1.
Such loads are still subject to on-highway inspection. If the load is not
adequately secured, the driver and/or carrier could be cited for a violation.
2.18
Add additional
securing devices
Responsibility
of
Driver
Inspect cargo and
securing devices3 3 3
Adjust cargo
and/or
securing devices
As necessary As necessary As necessary
As necessary As necessary As necessary
Within
first
50 miles
When duty
status of
driver changes
After 3 hours
or
150 miles
Minimum Number of
Indirect Tiedowns
Article
Description
All cargo1 tiedown for every 10 ft.,
or part thereof
1. As required by state and federal regulations, who is responsible for
proper load securement?
2. A driver is required to check the cargo and its securing devices within
how many miles after beginning a trip?
3. What is the maximum working load limit of a binder with a handle
marked “3/8-G7, 7/16-G43”?
4. A 5/8-inch chain that has a working load limit of 13,000 lbs. should
have links marked with what strength rating?
5. What is the working load limit of unmarked 2-inch synthetic
webbing?
6. If a metal coil is secured with 3/8-inch chains that do not display a
grade rating, what is the default strength rating assigned to each chain?
2.19
TEST YOUR KNOWLEDGE OF SECTION 2
Preventing Securement Failure
l Use a securement system to immobilize metal coils to ensure they are
prevented from sliding, tipping or rolling.
l Comply with specific securement methods required in regulations.
Application:
The following securement requirements are for metal coils transported on
flatbed vehicles, van-type vehicles or intermodal containers that have
anchor points. Securement requirements for sided vehicles or intermodal
containers without anchor points are covered at the end of this section.
3.1
SECTION 3 METAL COILS
NYS COMMERCIAL
DRIVER LICENSE
WITH
METAL COIL
ENDORSEMENT
(“M”)
Metal coil shipments
that weigh 5,000 lbs.
or more, individually
or bundled together
Metal coil shipments
that weigh less than
5,000 lbs.,
individually or
bundled together
NYS COMMERCIAL
DRIVER LICENSE
(“M” endorsement
not required)
License
Requirements
Cargo
Securement
Requirements
Metal Coil(s)
and Weight
GENERAL
CARGO
SECUREMENT
RULES APPLY
METAL COIL
SPECIFIC
SECUREMENT
RULES APPLY
Coil OrientationSecurement requirements for metal coils vary based on the orientation of
the eye of the coil on the vehicle. The three possible orientations are: eyes
vertical, eyes crosswise, and eyes lengthwise.
Eyes vertical
Eyes crosswise
Eyes lengthwise
3.2
Securement Requirements for a Single Metal Coil with
Eye Vertical
If the coil is fastened to a pallet, the pallet must be strong enough so it
cannot collapse under the forces described in the performance criteria
(Section 1).
Tiedowns must be arranged in the following manner to prevent the coils
from tipping in the forward, rearward and side-to-side (lateral) directions:
l at least one indirect tiedown attached diagonally from the left side of
the vehicle, across the eye of the coil, to the right side of the vehicle;
l at least one indirect tiedown attached diagonally from the right side of
the vehicle, across the eye of the coil, to the left side of the vehicle;
l at least one indirect tiedown attached side-to-side over the eye of the coil;
l either blocking and bracing, friction mats or direct tiedowns must be
used to prevent forward - rearward movement.
Note: Use a friction mat under the pallet to increase the friction between
the pallet and the deck.
The coil should be secured to the pallet to withstand all the forces
in the performance criteria (Section 1).
The sum of the working load limits from all tiedowns must be
at least 50% of the weight of the coils.
3.3
Securement Requirements for a Row of Metal Coils with
Eyes Vertical
Coils that are transported in rows must be secured by:
l at least one direct tiedown against the front of the row of coils,
restraining against forward motion, and if practicable, making an
angle 45 degrees or less with the floor.
l at least one direct tiedown against the rear of the row of coils,
restraining against rearward motion, and if practicable, making an
angle 45 degrees or less with the floor.
l at least one indirect tiedown over the top of each coil or side-by-side
row of coils, restraining against vertical motion. Indirect tiedowns
going over the top of a coil must be as close as possible to the eye
of the coil.
l direct tiedowns, blocking or bracing must be arranged to prevent
shifting or tipping in all directions.
Note: If there are more than two coils in the front and rear rows, the
direct tiedown must run outside some kind of channel that bears
against all coils in these rows.
Use a friction mat under each pallet to increase the friction between
the pallet and the deck. This should always be done when the
deck or coil is soaked with oil.
3.4
Securement Requirements for Metal Coils With Eyes Crosswise
Step #1: Support the Coil
To prevent rocking, the coil must be supported above the deck.
The coil supports must be held in place so they do not become loose
during a trip.
If timbers, chocks or wedges are used, they must be held in place by coil
bunks or similar devices to prevent them from coming loose.
The use of nailed blocking or cleats as the sole means to secure timbers,
chocks or wedges, or a nailed wood cradle, is prohibited.
The cradle can be restrained against sliding by placing friction mats under
the timbers and coil bunks, using nailed wood blocking or cleats against the
front timber, or by placing a direct tiedown around the front of the cradle.
If a direct tiedown is used around the front of the cradle, it does not count towards
the aggregate working load limit for tiedowns through the eye of the coil.
3.5
Step #2: Prevent the Coil from Forward Movement
At least one direct tiedown is required through its eye, restricting forward
motion.
Step #3: Prevent the Coil from Rearward Movement
At least one direct tiedown is required through its eye, restricting
rearward motion.
If more than two chains are required, they should be placed
symmetrically on either side of the coil. If an odd number of chains are
required, the last chain should be to the rear.
When transporting metal coils with the eyes crosswise, attaching direct
tiedowns diagonally through the eye of a coil to form an X-pattern is
prohibited:
3.6
Securement Requirements for Individual Metal Coils with
Eyes Lengthwise
There are three options for safely securing individual coils that are loaded
with their eyes lengthwise.
Securement Option #1
Step #1: Support the coil above the deck to prevent the coil from rolling.
Step #2: Attach at least one direct tiedown on each diagonal through the
eye of the coil making an angle not more than 45 degrees with
the floor of the vehicle when viewed from the side.
Step #3: Attach at least one indirect tiedown side-to-side over the top of
the coil.
Step #4: Use blocking or friction mats to prevent forward movement.
3.7
3.8
Securement Option #2:
Same as Option #1, except the direct tiedowns are straight instead of diagonal.
Securement Option #3:
As with Options #1 and #2, begin by supporting the coil above the deck
to prevent rolling.
In Option #3, two indirect tiedowns are attached over the front and rear
parts of the coil. Use blocking or friction mats to prevent forward
movement.
3.9
Securement Requirements for a Row of Metal Coils with
Eyes Lengthwise
A row of coils is made up of three or more coils loaded in like mode and
in a line. The requirements for securing a row of coils is similar to
securing individual coils (Option #3).
Step #1: Support the coils above the deck to prevent the coils from
rolling. The means to support the coils (for example, timbers,
chocks or wedges, a cradle, etc.) must not become unfastened or
loose while the vehicle is in transit.
Step #2: Attach at least two indirect tiedowns over each coil or side-by-
side row.
Step #3: Use blocking or friction mats to prevent front-to-back
movement in the forward direction.
Securement Requirements for Metal Coils in Sided Vehicles or
Intermodal Containers without Anchor Points
NOTE: Although the vehicle is not equipped with anchor points, the coil
itself or a tiedown attached to itself would form an anchor point. See the
definition of anchor point on page 4.1. Example: A tiedown may travel
through the vehicle structure and is attached to itself around the coil,
forming indirect securement.
Coils must be prevented from horizontal movement or from tipping by
the use of the following:
l friction mats
l system of blocking and bracing
l tiedowns and blocking
l tiedowns and bracing
The carrier/driver must ensure that the securement system meets the
Performance Criteria requirements in Section 1.
3.10
1. Transportation of one or more metal coils (individually or bundled
together) weighing 5,000 lbs. or more, must comply with which load
securement requirement?
2. How are tiedowns used to secure coils transported with eyes vertical on
a flatbed vehicle, in a sided vehicle or intermodal container with anchor
points?
3. What structure or device is used to prevent longitudinal movement of
the coil in the forward direction?
4. Which means of securement is prohibited when transporting coils with
the coil eye crosswise on the vehicle?
5. The sum of the working load limits (WLL) from all tiedowns must be
at least what percentage of the weight of the coils?
6. When is use of a friction mat recommended?
7. What are the requirements for securing metal coils with eyes
lengthwise?
3.11
TEST YOUR KNOWLEDGE OF SECTION 3
Aggregate working load limit - The aggregate working load limit is the
sum of:
1. One-half the working load limit of each tiedown that goes from
an anchor point on the vehicle to an anchor point on an article
of cargo;
2. One-half the working load limit of each tiedown that is attached to
an anchor point on the vehicle, passes through, over, or around the
article of cargo, and is then attached to an anchor point on the same
side of the vehicle;
3. The working load limit for each tiedown that goes from an anchor
point on the vehicle, through, over, or around the article of cargo,
and then attaches to another anchor point on the other side of
the vehicle.
Anchor point - Part of the structure, fitting or attachment on a vehicle or
article of cargo to which a tiedown is attached.
Article of cargo - A unit of cargo, other than a liquid or gaseous cargo,
that includes articles grouped together so they can be handled as
a single unit or can be grouped together by wrapping, strapping,
banding or edge protection device(s).
Blocking - A structure, device or another substantial article placed
against or around an article of cargo to prevent horizontal movement
of the article of cargo.
Bracing - A structure, device, or another substantial article placed against
an article of cargo to prevent it from tipping, that may also prevent it
from shifting.
Dunnage - All loose materials used to support and protect cargo.
Edge protector - A device placed on the exposed edge of an article to
distribute tiedown forces over a larger area of cargo than the tiedown
itself, to protect the tie-down and/or cargo from damage, and to allow
the tiedown to slide freely when being tensioned.
Friction mat - A device placed between the deck of a vehicle and an
article of cargo, or between articles of cargo, intended to provide
greater friction than exists naturally between these surfaces.
4.1
DEFINITIONS
"g " - The acceleration due to gravity, 32.2 ft/sec\2\ (9.823 m/sec\2\).
Metal Coil - A product comprised of mixtures, compounds and/or alloys
commonly known as metal, metal foil, metal leaf, forged metal,
stamped metal, metal wire or metal chain that are generally good
conductors of electricity and heat, and that can be melted or fused,
hammered into thin sheets, or drawn into wire, that are bulk packaged
or packaged from a continuous pull or multiple pulls as a roll, coil,
spool, wind or wrap, and where the aggregate weight of the coil is
equal to or greater than 5,000 pounds.
Sided vehicle - A vehicle whose cargo compartment is enclosed on all
four sides by walls of sufficient strength to contain articles of cargo,
where the walls may include latched openings for loading and
unloading. Includes vans, dump bodies, and a sided internodal
container carried by a vehicle.
Tiedown - A combination of securing devices which forms an assembly
that attaches articles of cargo to, or restrains articles of cargo on, a
vehicle or trailer, and is attached to anchor point(s).
Tractor-pole trailer - A combination vehicle that carries logs lengthwise
so they form the body of the vehicle. The logs are supported by a
bunk located on the rear of the tractor, and another bunk on the
skeletal trailer. The tractor bunk may rotate about a vertical axis, and
the trailer may have a fixed, scoping or cabled reach, or other
mechanical freedom, to allow it to turn.
Void filler - Material used to fill a space between articles of cargo and the
structure of the vehicle, that has sufficient strength to prevent
movement of the articles of cargo.
Working load limit (WLL) - The maximum load that may be applied to a
component of a cargo securement system during normal service,
usually assigned by the manufacturer of the component.
4.2
The NYS Department of Motor Vehicles wishes to thank the staff of the
NYS Department of Transportation and the Canadian Council of Motor
Transport Administrators (CCMTA) who contributed their time and
expertise to the North American Metal Coil Cargo Securement Program,
on which the materials in this manual are based.
ACKNOWLEDGMENTS
Andrew M. Cuomo
Governor
MV-79 (5/17)